Systems and methods for three-dimensional extraction of target particles ferrofluids

ABSTRACT

Systems, methods and devices are presented for extracting target particles within a ferrofluid medium. In some embodiments, a fluidic channel receives a flow of a mix of one or more types of target particles, where at least one magnetic field source is configured to react with the flow such that a force (indirect or direct) is placed on the particles of the mix, across the width and/or the height of the fluidic channel. An extraction opening placed on one wall is provided and configured to extract at least one type of target particle.

RELATED APPLICATIONS

This application claims benefit under 35 USC 119(e) of U.S. provisionalpatent application No. 61/794,607, filed Mar. 15, 2013, and entitled,“3D Extraction in Biocompatible Ferrofluids,” the entire disclosure ofwhich is herein incorporated by reference in its entirety.

FIELD OF THE DISCLOSURE

The present disclosure relates to extraction in biocompatibleferrofluids and in particular, to systems and methods for separating acells and/or other target particles suspended in a ferrofluid (e.g., abiocompatible ferrofluid).

BACKGROUND OF THE DISCLOSURE

As shown in FIG. 1, as the inventor's prior disclosures describe, i.e.,WO2011/071912 and WO2012/057878, concentrating and extracting targetmoieties within microfluidics may be accomplished two-dimensionally, byplacing a ferrofluid containing the target moieties within at least onemicro/flow channel, and applying a magnetic field. The magnetic field isconfigured to effect an indirect force on the target moieties such thatthey are focused/separated into different streamlines of particlesacross the width of the flow channel. The streamlines that carry thetarget moieties are then extracted at the end of the channel viamultiple outlets in the plane of the flow channel.

To that end, such approaches may be limited by the resolution with whichthe width of the streamlines carrying the focused moieties are alignedwith a particular outlet channel for extracting those streamlines.Pulsations, or other non-steady pressure effects originating from, forexample, pumps, geometry/elasticity of liquid channels/connectors,trapped air bubbles, partial blockages due to particles flowing throughnarrow geometries, and the like, can all add to time-dependentdeviations in the ultimate trajectories of the target moieties.

SUMMARY OF THE DISCLOSURE

Embodiments of this disclosure correspond to further developments andapplications of the inventor's previous series of disclosures,including, for example PCT publication no. WO2011/071912 andWO2012/057878, the noted disclosures of which are all hereinincorporated by reference in their entireties.

Accordingly, in some embodiments, a method for extracting particleswithin a ferrofluid medium is provided. The method may comprise flowinga mix comprising a ferrofluid medium containing one or more types oftarget particles through at least one microfluidic channel. The at leastone channel having a first inlet portion for receiving the flow and asecond portion spaced downstream from the first portion, a first sidespaced away from a second side and comprising to a width of the channel,and a third side spaced away from a fourth side and comprising a heightof the channel, wherein the mix flows through the channel in a firstdirection from the first portion to the second portion. The method mayalso include applying a magnetic field adjacent at least one of thesides of the channel, the magnetic field configured to concentrate atleast one type of target particle contained in the mix medium within awidth region comprising a portion of the width and a height regioncomprising a portion of the height, the height region being located ator adjacent to the third side, such that the at least one first type oftarget particles from the flow are concentrated within the width regionand the height region creating a concentrated flow of target particles.The method may also include extracting a flow of concentrated targetparticles of the first type from the mix via an extraction openingarranged on the third side at or near the second portion, where the flowof target particles of the first type from the extraction openingincludes an exit velocity.

In some embodiments, a system for extracting particles within aferrofluid medium is provided. Such embodiments may include at least onemicrofluidic channel having a first inlet portion and a second portionspaced downstream from the first portion for receiving a flow of a mixcomprising a ferrofluid medium containing one or more types of targetparticle, a first side spaced away from a second side and comprising awidth of the fluidic channel, and a third side spaced away from a fourthside and comprising a height of the fluidic channel. The fluid flowsthrough the fluidic channel in a first direction from the first end tothe second end. The system may also include magnetic field meansarranged adjacent at least one of the sides of the fluidic channel, themagnetic field configured to focus at least one type of target particlescontained in the ferrofluid medium flow within a width region comprisinga portion of the width and a height region comprising a portion of theheight. The height region being located at or adjacent to the thirdside, such that the target particles from the flow are concentratedwithin the width region and the height region creating a concentratedflow of particles. The system may further include an extraction openingarranged on the third side at or near the second end, the extractionopening configured to receive and direct the concentrated flow of targetparticles from the fluidic channel at an exit velocity.

Embodiments of the disclosure may further include one or more of thefollowing features:

-   -   the target particles comprise at least one of target moieties        and target biological cells;    -   the extraction opening having a shape comprising round,        circular, square, a slit, rectangular, triangular and        elliptical;    -   the magnetic field means comprises at least one of one or more        current-carrying electrodes and one or more magnets;    -   velocity adjustment means;    -   the velocity adjustment means comprises flow resistance means;    -   the velocity adjustment means comprises at least one of:        adjusting the magnetic field to effect forces on the flow        affecting the exit velocity, the size of the extraction opening        is configured to increase velocity, controlling the flow        resistance from the extraction opening, and providing at least        one of a pressure sink and a flow sink arranged downstream of        the extraction opening.

The above-noted embodiments, as well as other embodiments, will becomeeven more evident with reference to the following detailed descriptionand associated drawing, a brief description of which is provided below.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is the illustrative structures of a microfluidic platform thatperforms concentration/enrichment of a target moiety.

FIG. 2 is a schematic illustration of a system for extracting targetparticles from a ferrofluid medium according to some embodiments of thepresent disclosure.

FIG. 3 is a schematic illustrating a flow simulation depicting flowstreamlines in close proximity to the exit opening of a microfluidicchannel according to some embodiments of the present disclosure.

DETAILED DESCRIPTION OF SOME OF THE EMBODIMENTS

FIG. 1 shows a top view of a microfluidic channel 10 configured toperform concentration/enrichment of target particles 12 (e.g., moieties)from a ferrofluid flow 11 (e.g., comprising a mix of target particlesand a ferrofluid medium). In such cases, the alignment of the focusedtarget particles with an outlet 14 stream determines the concentrationefficiency and loss. As is shown, magnetic field means 8 (which maycomprise at least one of an electrode, a permanent magnet, and anelectromagnet) applies a magnet field which is configured to focustarget particles of the mix in a stream (e.g., see focusing boundaries6). Misalignments due to device construction or pressure variations maylimit the effective enrichment factor. While the magnetic field meansare shown simply as two bars above/below the schematic of the channel,it is understood that the magnetic field means may be positionedanywhere relative to the flow which would affect the functionality offocusing/separating target particles (see, e.g., WO2011/071912 andWO2012/057878)

FIG. 2 illustrates concepts according to some embodiments, which may bereferred to as “blow-hole” extraction. In such embodiments, for example,target particles 22 are suspended in a magnetic liquid medium 21 (e.g.,a ferrofluid medium) forming a mix, where the target particles maycomprise one or more types of particles (e.g., one more types ofbiological particles—e.g., cells, moieties, and the like), and flowedthrough one or more microfluidic channels 20 of an extraction and/ormicrofluidic system. Types of target particles also may be (and may bein addition to being a biological particle) based on at least one ofsize, shape, features, mass and charge. The fluidic channel(s) 20 may beprovided for in a cartridge configured to be removable from a generalsystem for each new particle extraction. Magnetic field applying means26, which may comprise any one or more of electrodes and magnets, may bepositioned adjacent at least one side of the fluidic channel, and aresimply shown adjacent the channel in FIG. 2; however, it will beunderstood that the magnetic field means is positioned relative to thechannel(s) to effect the separation functionality of at least some ofthe embodiments taught by this disclosure.

In some embodiments, the magnetic fields are configured to act upon themix/ferrofluid 21 such that target particles 22 are concentrated,focused, or otherwise separated (these terms used interchangeablythroughout), along a portion of the flow. For example, in someembodiments, a fluidic cartridge, having for example parallelmicrofluidic channels 20, is arranged adjacent (e.g., on top of) one ormore current-carrying electrodes and/or magnets. Upon activation of themagnetic field, the target particles 22 become concentrated, forexample, along a central portion of the fluid flow from an inlet 24end/portion to an outlet end/portion 25 (e.g., an end/portion of thechannel which is spaced apart from the inlet end), and, in someembodiments, the magnetic field also is configured to concentrate thetarget particles along one side of the fluidic channel.

For example, if the magnetic field means is placed below the cartridge,it may be configured to direct the target particles in a concentratedstream within the center of the fluid flow, and may also (or in placeof) concentrate the target particles along the “ceiling” (e.g., a side)of the channel (relative to the “floor” of the channel, in, for example,a vertical direction).

Accordingly, in some embodiments, an extraction opening/orifice/hole 23is arranged downstream from the inlet end 24 of the channel 20, on the“ceiling” side, from which the concentrated flow of target particles(e.g., the target particles themselves) may be extracted therefrom (FIG.2). The velocity or speed of the flow of concentrated target particlesfrom the extraction opening 23 may be adjusted either passively, bycontrolling flow resistance of the extraction orifice or main ferrofluidflow, and/or actively via the incorporation of a pressure of flow sinkdownstream of the extraction orifice (e.g., an outlet to themicrofluidic channel). Likewise, the magnetic field may be configured toeffect the velocity, in some embodiments, of particles being extractedvia the extraction opening. The extraction opening 23 is downstream ofthe inlet 24, in some embodiments, sufficiently far from the inlet 24that the particles 22 being manipulated have had time to be pushed up tothe channel ceiling and concentrated into a tight stream. Hence, thedistance configured is based on at least one of flow rate, magneticfield intensity and size of the particles being manipulated. In someembodiments, the distances may be in range of between about 0.5-5 cm. Asfor the size of the extraction opening size, in some embodiments, thesize may be between about 100 to about 1000 μm.

In some embodiment, the focusing resolution achieved in the plane of thefluidic channel 10 (e.g., the x-y plane in FIGS. 1 and 2) may besupplemented by the localization field/power achieved in the normaldirection (i.e., the z-axis in FIGS. 1 and 2). Since target particles 12(e.g., cells and/or other microscale moieties) suspended in a ferrofluid11 may be directed towards a wall of the fluidic channel 10 (e.g.,externally applied magnetic fields via the magnetic field means), theaverage distance from the specific wall and the target particles mayeffectively become their corresponding average radii as the particlesinteract (e.g., roll) on the wall—and thus, become flow streamlines ofsuch particles. Accordingly, in some embodiments, the exit flow ratethrough the extraction channel (relative to the main channel's flowrate) may be engineered to be sufficient enough to attract flowstreamlines having distances from the wall slightly larger than theaverage radius of the focused target particles. According to suchembodiments, these focused target particles may then be extractedthrough the extraction orifice. In some embodiments, the wall height isconfigured to be greater than the largest particle within the ferrofluidmix, and may be, for example, between about 10-1000 μm.

For example, FIG. 3 shows a flow simulation depicting flow streamlinesfor target particle 31 extraction which are in close proximity to theextraction opening 32. In such embodiments, and as an example, targetparticles 31 (e.g., cells of about 2 microns in diameter) are pushed viaat least one of the ferrofluid flow and magnetic field, to within 1micron of the upper channel (i.e., ceiling). Conservatively, theextraction orifice/geometry may be configured to yield a predeterminedextraction margin, which in some embodiments may be near or equal to100%, less than 100% or between about 75% and 100%, or a majority. Thusin a nearly 100% margin configuration, streamlines that are about 2microns below the channel ceiling, and (in some embodiments) co-linearwith the location of the extraction opening 32, may be attracted to theextraction opening 32 for extraction (FIG. 3). In another example, for aflow channel 30 that is 50 microns deep, which may yield a boost ofabout 25 times (50/2) the concentration factor already achieved alongthe x-y plane. Hence, in some embodiments, concentration factors on theorder of between about 250-500 may be realized.

Any and all references to publications or other documents, including butnot limited to, patents, patent applications, articles, webpages, books,etc., presented in the present application, are herein incorporated byreference in their entirety.

Example embodiments of the devices, systems and methods have beendescribed herein. As noted elsewhere, these embodiments have beendescribed for illustrative purposes only and are not limiting. Otherembodiments are possible and are covered by the disclosure, which willbe apparent from the teachings contained herein. Thus, the breadth andscope of the disclosure should not be limited by any of theabove-described embodiments but should be defined only in accordancewith claims supported by the present disclosure and their equivalents.Moreover, embodiments of the subject disclosure may include methods,systems and devices which may further include any and all elements fromany other disclosed methods, systems, and devices, including any and allelements corresponding to target particle separation,focusing/concentration. In other words, elements from one or anotherdisclosed embodiments may be interchangeable with elements from otherdisclosed embodiments. In addition, one or more features/elements ofdisclosed embodiments may be removed and still result in patentablesubject matter (and thus, resulting in yet more embodiments of thesubject disclosure). Correspondingly, some embodiments of the presentdisclosure may be patentably distinct from one and/or another referenceby specifically lacking one or more elements/features. In other words,claims to certain embodiments may contain negative limitation tospecifically exclude one or more elements/features resulting inembodiments which are patentably distinct from the prior art whichinclude such features/elements.

1. A method for extracting particles within a ferrofluid medium, themethod comprising: flowing a mix comprising a ferrofluid mediumcontaining one or more types of target particles through at least onemicrofluidic channel, the at least one channel having: a first inletportion for receiving the flow and a second portion spaced downstreamfrom the first portion, a first side spaced away from a second side andcomprising to a width of the channel, and a third side spaced away froma fourth side and comprising a height of the channel, wherein the mixflows through the channel in a first direction from the first portion tothe second portion; applying a magnetic field adjacent at least one ofthe sides of the channel, the magnetic field configured to concentrateat least one type of target particle contained in the mix within a widthregion, the width region comprising a portion of the width, and a heightregion, the height region comprising a portion of the height located ator adjacent to the third side, such that the at least one first type oftarget particles from the flow are concentrated within the width regionand the height region, creating a concentrated flow of target particlesof the at least one first type; and extracting the concentrated flow oftarget particles via an extraction opening arranged on the third side ator near the second portion, wherein the concentrated flow of targetparticles from the extraction opening includes an exit velocity.
 2. Themethod of claim 1, wherein concentrating comprises at least one ofseparating, focusing and concentrating.
 3. The method of claim 1,wherein a type of particles corresponds to at least one of a size,shape, mass, and charge of one or more particles.
 4. The method of claim1, wherein the first type of target particles comprises at least one oftarget moieties and target biological cells.
 5. The method of claim 1,wherein applying a magnetic field includes at least one ofcurrent-carrying electrodes and magnets.
 6. The method of claim 1,further comprising adjusting the exit velocity of the concentrated flowof target particles by at least one of: configuring the magnetic fieldto effect forces on the flow affecting the exit velocity, configuringthe size of the extraction opening to increase velocity, controlling theflow resistance from the extraction opening, and providing at least oneof a pressure sink and a flow sink arranged downstream of the extractionopening.
 7. A system for extracting particles within a ferrofluidmedium, the system comprising: at least one microfluidic channel havinga first inlet portion and a second portion spaced downstream from thefirst portion for receiving a flow of a mix comprising a ferrofluidmedium containing one or more types of target particles, a first sidespaced away from a second side and comprising a width of the fluidicchannel, and a third side spaced away from a fourth side and comprisinga height of the fluidic channel, wherein fluid flows through the fluidicchannel in a first direction from the first end to the second end;magnetic field means arranged adjacent at least one of the sides of thefluidic channel, the magnetic field configured to focus at least onetype of target particles contained in the ferrofluid medium flow withina width region, the width region comprising a portion of the width, anda height region, the height region comprising a portion of the heightlocated at or adjacent to the third side, such that the target particlesfrom the flow are concentrated within the width region and the heightregion creating a concentrated flow of particles; and an extractionopening arranged on the third side at or near the second end, theextraction opening configured to receive and direct the concentratedflow of target particles from the fluidic channel at an exit velocity.8. The system of claim 7, wherein the target particles comprise at leastone of target moieties and target biological cells.
 9. The system ofclaim 7, wherein the magnetic field means comprises at least one of: oneor more current-carrying electrodes and one or more magnets.
 10. Thesystem of claim 7, further comprising velocity adjustment means.
 11. Thesystem of claim 10, wherein the velocity adjustment means comprises flowresistance means.
 12. The system of claim 10, wherein the velocityadjustment means comprises at least one of adjusting the magnetic fieldto effect forces on the flow affecting the exit velocity, the size ofthe extraction opening is configured to increase velocity, controllingthe flow resistance from the extraction opening, and providing at leastone of a pressure sink and a flow sink arranged downstream of theextraction opening.